Polarization-maintaining dispersion-compensation microstructure fiber

We claim: 1. A polarization-maintaining dispersion-compensation microstructure fiber, wherein pure silica glass is used as a base material; the fiber comprises an inner core, a single-layer air-hole array surrounding the inner core, an inner cladding air-hole array, an air-hole array in an outer core, a single-layer air-hole array surrounding the outer core, and an outer cladding air-hole array; the single-layer air-hole array surrounding the inner core and the inner cladding air-hole array are collectively referred to an air-hole array in a first area; the air-hole array in the outer core, the single-layer air-hole array surrounding the outer core, and the air-hole array in the outer core are collectively referred to an air-hole array in a second area; the air-hole array in the first area includes 3 rows of air holes arranged in a square lattice arrangement with an adjacent air hole spacing Λ; in the first area, two air holes in a middle row are omitted to form the inner core; a midpoint of a line connecting centers of the two omitted air holes are defined as a coordinate original point; an axis connecting the centers of the two omitted air holes is defined as y-axis; an axis passing through the original point and perpendicular to the y-axis is defined as the x-axis; a diameter of the air holes in the single-layer air-hole array surrounding the inner core is d1; the air holes in the air-hole array in the second area are arranged in square lattice arrangement with the adjacent air hole spacing Λ; the second area contains two sub-areas that are located outside the first area in the x-direction; the air-hole arrays in the first and second areas are separated by Λ along x-direction, and dislocated by Λ/2 along y-direction; two outer cores are respectively located in the two sub-areas of the second area and are symmetrically distributed with respect to the y-axis; the two outer cores have an identical structure; each of the two outer cores contains the air-hole array in the outer core and each air-hole array in the outer core comprises two air holes with a diameter d3; four air holes with the diameter d3 are located on a positive x-axis and a negative x-axis respectively, with distances of 3Λ and 4Λ measured from the centers of the air holes to the original point, respectively; a diameter of the air holes in the single-layer air-hole array surrounding the outer core is d2; a diameter of the air holes in the inner cladding air-hole array and the outer cladding air-hole array are both d4; the four diameters satisfy the relationship of d1>d2>d4>d3. 2. The fiber according to claim 1 , wherein the air holes in the air-hole array in the first area and the air-hole array in the second area use the adjacent air hole spacing Λ in a range of 2.288-2.298 μm. 3. The fiber according to claim 1 , wherein the diameter d1 of the air holes in the single-layer air-hole array surrounding the inner core is in a range of 1.601-1.611 μm. 4. The fiber according to claim 1 , wherein the diameter d3 of the two air holes included in the air-hole array in the outer core is in a range of 0.224-0.234 μm. 5. The fiber according to claim 1 , wherein the diameter d2 of the air holes in the single-layer air-hole array surrounding the outer core is in a range of 1.372-1.382 μm. 6. The fiber according to claim 1 , wherein the diameter d4 of the air holes in the inner cladding and the outer cladding air-hole arrays is in a range of 1.055-1.065 μm. 7. The fiber according to claim 1 , wherein the inner cladding air-hole array directly above or below the single-layer air-hole array surrounding the inner core contains more than 1 row of air holes; and the two sub-areas of the air-hole array in the second area contains more than 5 rows and 5 columns of air holes.